KR100243218B1 - Data decoding apparatus and the method - Google Patents

Abstract

The present invention discloses a data decoding apparatus and a method thereof. In the present invention, when the digital magnetic recording and reproducing apparatus and the reproduction signal are decoded, the noise corresponds to the E ⁿ PR4 system and the aperture ratio of the eye pattern corresponds to the PR (+1, -1) system, thereby improving the performance of the Viterbi decoder. At the same time, the Viterbi decoder is composed of one channel by enabling detection in the PR (+1, -1) system. In addition, the present invention has the effect that the data can be decoded in various types as well as the corresponding type in the system having the PR4 type or E ⁿ PR4 type channel.

Description

Data decoding device and method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of data decoding, and in particular, in a digital recording / reproducing apparatus having a PR4 type or E ⁿ PR4 type channel, a data decoding device for greatly reducing hardware by decoding data using a best-practice decoder composed of one channel, and It's about how.

As a method of increasing the recording density by signal processing without significantly changing the characteristics of the existing recording and reproducing apparatus, PRML (Partial Response Maximum Likelihood) related technologies including Viterbi decoding processing have been advanced, and many concrete means have been proposed. have.

A block diagram of a digital video cassette recorder (VCR) having such PR4 (1, 0, -1) type channels is shown in FIG. In Fig. 1, a Non-Return to Zero Inversion (NRZI) converter 102 converts an input signal into an NRZI code representing 1 or -1. Precoder 108 converts the NRZI code back to an interleaved NRZI code. Here, the NRZI converter 102 and the precoder 108 are configured to have a characteristic of 1/1 + D. D stands for 1-bit delay (unit delay) of the recording data, and the configuration of 1/1 + D means that the signal delayed by the input signal and the delayer such as the NRZI converter 102 and the precoder 108 is output by exclusive OR. At the same time, the exclusive OR signal is fed back to the delay unit.

On the other hand, the reproduction amplifier 116 of the regeneration system amplifies the reproduced signal through the channel 114 having the 1-D characteristic (differential characteristic), wherein the amplified reproduction signal is a PR (+1, -1) type signal to be. The equalizer 118 compensates for the waveform distortion and amplitude distortion of the signal amplified by the reproduction amplifier 116, and the channel demodulator 120 having the 1 + D characteristic (integral characteristic) is a PR output from the equalizer 118. Convert a (+1, -1) type signal to a PR4 (+1, 0, -1) type signal. That is, the channel demodulator 120 has a 1 + D characteristic, which is an inverse characteristic of 1/1 + D, corresponding to the precoder 108 having a 1/1 + D characteristic, thereby improving noise characteristics and an eye pattern. ), The aperture ratio decreases. The timing detector 140 detects the timing of the reproduced signal equalized by the equalizer 118 by using an inherent phase locked loop (PLL) and outputs a driving clock required for the equalizer 118 and the likelihood decoder 126. .

Here, since the recorder of the digital recording / reproducing apparatus having the PR4-type channel is composed of two delayers, a four-state Viterbi decoder having two or ^two playback systems is required, but the digital VCR has two (1 + D) channels. Since it is interleaved, a two-state Viterbi decoder is required. That is, the likelihood decoder 126 shown in FIG. 1 configures two state detectors 130 and 132 and two Viterbi decoders 134 and 136 performing the same function in parallel, respectively, and the demultiplexer 128 The multiplexer 138 operates according to a driving clock output from the timing detector 140, and decoded data is output from the multiplexer 138.

The reason for configuring the state detector and the Viterbi decoder in two channels is to convert the PR4 (+1, 0, -1) type data output from the channel demodulator 120 into the partial response PR (+1, -1) type. "0" or "-1" is read after "+1", "+1" is never read, and equally "0" or "+1" is read after "-1" and "-1". "Is to apply the Viterbi algorithm by satisfying the condition that is never read.

In addition, a digital VCR having a PR4-type channel shown in Fig. 1 is also referred to as a PRML-type system in the case of decoding data using a best-number decoding algorithm such as a Viterbi decoding algorithm.

FIG. 2 is a block diagram of a digital recording / reproducing apparatus having an EPR4 (1, 1, -1, -1) type channel having the easiest configuration among E ⁿ PR (Extended Partial Response) 4 types. Detailed description of the same configuration will be omitted. An example of the digital recording / reproducing apparatus having the EPR4-type channel is a hard disk driver (HDD).

In FIG. 2, the precoder 208 has 1 / (1 + D) ² characteristics with one more delay compared to the PR4 type system shown in FIG. 1, and the precoder 208 has the EPR4 (1, It is called 1, -1, -1) type. Recording system, all reproduction system so that constituting the three delay becomes 2 ³ or eight Viterbi decoder (250-264) and eight state detectors (234-248) of the status is required. In addition, the channel demodulator 222 has a 1 / (1 + D) ² characteristic corresponding to the precoder 208 having a 1 / (1 + D) ² characteristic. 2, SD denotes a state detector, VD denotes a Viterbi decoder, and the driving clock CK output from the timing detector 268 is a demultiplexer 232 and first to eighth Viterbi decoders 250. -264) and multiplexer 266.

FIG. 3 is a block diagram conceptualizing a digital recording / reproducing apparatus having an E ⁿ PR 4 type channel. In response to a precoder 304 having a 1 / (1 + D) ^{n + 1} characteristic, the channel demodulator 312 is (1). + D) configured to have ^{n + 1} characteristics, the likelihood demodulator 314 demultiplexes the outputs of 2 ^{n + 2} Viterbi decoders, 2 ^{n + 2} state detectors, and channel demodulator 312 to 2 ^{n + 2} And a multiplexer for outputting decoded data by multiplexing the outputs of 2 ^{n + 2} Viterbi decoders. Therefore, 2 ^{n + 2} state detectors and Viterbi decoders are configured in parallel, respectively, and demultiplexed of the demodulated data into 2 ^{n + 2} channels, independently decoded by a Viterbi decoder configured to correspond to each channel, and then multiplexed again. Doing. This divides the partial response E ⁿ PR4 type signal of the channel demodulator 312 into the partial response (1, -1) type signal so that "0" or "-1" is read after "+1" and "+". 1 "is never read out, and equally," 0 "or" +1 "is read after" -1 ", and" -1 "can be applied to satisfy the condition of never reading. It would be.

As a result, the EPR4 type system rather than the PR4 type system, and the E ² PR4 type system than the EPR4 type system, that is, the E ⁿ PR4 type system with large ^n, are more resistant to noise and the signal band is reduced, so that the recording density of the channel band is increased. However, the eye pattern is reduced and the complexity of the hardware is increased. In other words, the conventional PR4 type system should have 4 (two digital VCRs) best decoders in parallel, the ERP4 type system should have 8 best number decoders in parallel, and the E ⁿ PR4 type system has 2 ^{n +. Since the} two best decoders have to be configured in parallel, there is a problem in that the burden of hardware increases rapidly.

In order to solve the above problems, an object of the present invention is to reduce the hardware by decoding the data by the best-quality decoder consisting of one channel while maintaining the performance of the PR4-type system in the digital recording and reproducing apparatus having the PR4-type channel. The present invention provides a data decoding apparatus.

It is another object of the present invention to provide a device for digitally reproducing and reproducing a device having an E ⁿ PR 4 channel, in which noise is significantly reduced by decoding data by a best-quality decoder composed of one channel while maintaining the performance of the E ⁿ PR 4 system. To provide.

It is still another object of the present invention to provide an apparatus for selectively decoding data into a PR4 type or an E ⁿ PR4 type by using a best-quality decoder composed of one channel in a digital recording and reproducing apparatus in which data is recorded in the PR4 type. .

It is still another object of the present invention to provide an apparatus for decoding data in various types using a best-quality decoder composed of one channel in a digital recording and reproducing apparatus in which data is recorded in the E ⁿ PR4 type.

It is still another object of the present invention to decode data in a PR (+1, -1) state using a best-of-breed decoder consisting of one channel while maintaining the performance of a PR4-type system in a digital recording / reproducing apparatus having a PR4-type channel. To provide a way.

A further object is noise PR (+1, -1) by using choewooho decoder consisting of a channel while maintaining the performance of the E ⁿ PR4-type system in a digital recording and reproducing apparatus having an E ⁿ PR4 channel condition of the present invention The present invention provides a method of decoding data.

It is still another object of the present invention to provide a method for selectively decoding a PR4 type or E ⁿ PR4 type data using a best-quality decoder composed of one channel in a digital recording and reproducing apparatus in which data is recorded in PR4 type.

It is still another object of the present invention to provide a method of decoding data in various formats using a best-quality decoder composed of one channel in a digital recording and reproducing apparatus in which data is recorded in the E ⁿ PR4 type.

In order to achieve the above objects, the data decoding apparatus according to the present invention is a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, comprising one channel and receiving through a channel. Has a (1 + D) characteristic, which is an inverse characteristic of a precoder and a best-number decoder that outputs the best-decoded data by performing the most-decoded PR (+1, -1) type signal. It characterized in that it comprises a channel demodulator for outputting.

In addition, the data decoding apparatus according to the present invention has a (1 + D) characteristic in a system having an E ⁿ PR4 channel including a precoder having a 1 / (1 + D) ^{n + 1} characteristic, Prefilter for converting PR (+1, -1) type signal received through PR4 (+1, 0, -1) type signal, Forward threshold and division linked to PR (+1, -1) type signal It is a state detector that detects positive and negative state values according to the jaw value, and has 1 / (1 + D) characteristics, and it is a PR4 (+1, 0, -1) type signal by feeding back positive and negative state values. Converts the signal back into PR (+1, -1) type signal and outputs it to the status detector by n + 1 units connected in series and composed of one channel and PR (+1, -1) output from the unit A Viterbi decoder that outputs Viterbi decoded data by Viterbi decoding and a (1 + D) ^{n + 1} characteristic, which is an inverse characteristic of the precoder, and channel demodulates the Viterbi decoded data. And a channel demodulator for outputting decoded data.

In addition, the data decoding apparatus according to the present invention is a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, having a (1 + D) characteristic, and receiving a PR ( Pre-filter for converting +1, -1) type signal to PR4 (+1, 0, -1) type signal, and defined state according to the normal threshold and the subthreshold value linked to PR (+1, -1) type signal State detector for detecting value and negative state value, has 1 / (1 + D) characteristic and inputs positive state value and negative state value to regenerate PR4 (+1, 0, -1) type signal Viterbi decoding the PR (+1, -1) type signal output from the unit consisting of a unit connected in series with n + 1 reverse prefilters converted to a -1) type signal and output to the peak detector A Viterbi decoder that outputs Viterbi decoded data, and has a (1 + D) characteristic, which is an inverse characteristic of the precoder, and decodes the Viterbi decoded data into a PR4 type by channel demodulation. A first channel demodulator for outputting data, (1 + D) has the ⁿ characteristic, the second channel demodulator and a PR4 / E ⁿ PR4 to channel demodulating the output of the channel demodulator, which outputs the data decoded to the E ⁿ PR4-type And a selector for selecting one of the outputs of the first and second channel demodulators according to the mode signal.

In addition, the data decoding method according to the present invention is a data decoding method of a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristics, PR (+1, -1 received through the channel Outputting the most-decoded data by performing the most-decoded decoding of the) -type signal and adding the delayed data and the most-decoded data by delaying the most-decoded data by a unit bit to have (1 + D) characteristics, which are inverse characteristics of the precoder. And outputting decoded data.

In addition, the data decoding method according to the present invention provides a data decoding method of a system having an E ⁿ PR4 channel including a precoder having a 1 / (1 + D) ^{n + 1} characteristic, and the (1 + D) characteristic. PR4 (+1, 0, -1) signal by adding delayed signal and PR (+1, -1) signal by delaying PR (+1, -1) type signal received through channel In the first conversion step of converting the signal to PR, the PR4 (+1, 0, -1) type signal is subtracted from the feedback signal to have a 1 / (1 + D) characteristic and converted into a PR (+1, -1) type signal. A positive state value and a negative state value of the PR (+1, -1) type signal are detected according to the positive threshold value and the division threshold value linked to the converted PR (+1, -1) type signal. , A repeating step of repeating a feedback signal output step of adding a negative state value and an inverse positive state value, a first conversion step, a second conversion step, and a feedback signal output step n + 1 times, and a repeating step After carrying out Outputting the Viterbi-decoded data by Viterbi decoding the output PR (+1, -1) type signal and Viterbi-decoded data to have (1 + D) ^{n + 1} characteristics, which are inverse characteristics of the precoder. And adding the decoded data with n + 1 bit delay and Viterbi decoded data to output decoded data.

In addition, the data decoding method according to the present invention is a data decoding method of a system having a PR4-type channel including a precoder having 1 / (1 + D) characteristics, and has a (1 + D) characteristic through a channel. A first unit of delaying the received PR4 (+1, -1) type signal by adding a delayed signal and the PR (+1, -1) type signal to convert the PR4 (+1, -1) type signal into a PR4 (+1, 0, -1) type signal. Conversion step, the second conversion step of converting the PR4 (+1, 0, -1) type signal to the PR (+1, -1) type signal again by subtracting the PR4 (+1, 0, -1) type signal to have a 1 / (1 + D) characteristics The positive state value and the negative state value of the PR (+1, -1) type signal are detected according to the positive threshold value and the division threshold value linked to the converted PR (+1, -1) type signal. Outputs the feedback signal outputting the feedback signal plus the positive state value of the inverse phase, and repeats the repeating step of repeating the repeating step n + 1 times, the first conversion step, the second conversion step, and the feedback signal output step n + 1 times. Outputting the Viterbi-decoded data by Viterbi decoding the PR (+ 1, -1) type signal, and delaying the bitterby-decoded data to have (1 + D) characteristics, which are inverse characteristics of the precoder. Adding the delayed data and the Viterbi-decoded data to output the PR4-type decoded data, n-bit-delaying the PR4-type decoded data to have (1 + D) ⁿ characteristics, and delaying the n-bit delayed data and PR4-type decode. by adding the data includes selecting one of the data decoded in step and a PR4 / E ⁿ PR4-mode signal data and the E ⁿ PR4-type decoding the PR4-type in accordance with the outputting the data decoded by E ⁿ PR4-type It is characterized by.

1 is a block diagram of a digital video cassette recorder (VCR) having a PR4-type channel.

2 is a block diagram of a digital recording and reproducing apparatus having an EPR4 type channel.

3 is a block diagram of a digital recording and reproducing apparatus having an E ⁿ PR 4 channel.

4 is a block diagram according to an embodiment of a data decoding apparatus according to the present invention.

5 is a block diagram according to another embodiment of a data decoding apparatus according to the present invention.

6A to 6H are operational waveform diagrams of the data decoding apparatus shown in FIG.

7 is a block diagram according to another embodiment of a data decoding apparatus according to the present invention.

8 is a block diagram according to another embodiment of a data decoding apparatus according to the present invention.

(A) to (l) of FIG. 9 are operational waveform diagrams of the data decoding apparatus shown in FIG.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the data decoding apparatus and method according to the present invention.

4 is a circuit diagram according to an embodiment of a data decoding apparatus of a digital recording / reproducing apparatus having a PR4-type channel. In Fig. 4, the sampling & hold unit 410 samples & holds the equalized signal output from the equalizer (not shown). Here, the output state of the sampling and holding unit 410 maintains the analog value at the moment of sampling according to the driving clock generated by the timing detector 450, not "1" or "0" of the digital level.

The peak detector 420 is an example of implementing a state detector, and the positive peak value detector 423 and the volume value detector 425 are examples of the positive state value detector and the negative state value detector. A positive peak value detection threshold (hereinafter, abbreviated as a threshold) and a volume value detection threshold (hereinafter, referred to as a signal Vs) output from the sampling & hold device 410 of the peak detector 420. And the threshold value is controlled by the detected peak value of the opposite polarity, and the positive peak value Hn and the volume value Ln are detected from the equalized signal according to the set threshold value. do.

That is, the demultiplexer and amplifier of the peak detector 420 (denoted DEMUX & AMP: 421) detects only a positive value from the signal Vs output from the sampling & hold group 410, and thus a predetermined level. The positive signal Va amplified by the output signal is output to the first automatic threshold value adjustment (ATC) device 422 and the positive peak value detector 423, and the negative signal Va is amplified from the signal Vs output from the sampling & hold device 410. Only the value of-) is detected and the amplified sub-signal Vb is output to the second ATC device 424 and the bulk value detector 425.

The first ATC unit 422 automatically sets the threshold value Vra of "+1" for positive peak value detection in conjunction with the amplified positive signal Va output from the DEMUX & AMP 421, and the volume value At the time when the volume value of the active state (here, logic " 1 ") is detected in the detector 425, the threshold Vra of " + 1 " is reset to a predetermined value. The positive peak value detector 423 compares the forward threshold set by the first ATC device 422 with the amplified positive signal Va and outputs a positive peak value Hn corresponding to the amplified positive signal Va. At the same time, the positive peak value Hn is fed back to the second ATC device 424.

The second ATC device 424 automatically sets the threshold value Vrb of "-1" for volume value detection in conjunction with the amplified subsignal Vb output from the DEMUX & AMP 421, and the positive peak. At the time when the positive peak value of the active state (here, logic "1") is detected in the value detector 423, the threshold value Vrb of "-1" is reset to a predetermined value. The volume value detector 425 compares the division threshold set by the second ATC device 424 with the amplified sub-signal Vb and outputs a bulk value Ln corresponding to the amplified sub-signal Vb. At the same time, the volume Ln is fed back to the first ATC device 422. The positive peak value Hn and the bulk value Ln of the positive peak value detector 423 and the volume value detector 425 are digital data.

The peak detector 420 having such a configuration is disclosed in Korean Patent Application No. 97-30468 filed by the same applicant. However, any configuration may be used for the peak detector 420 of the present invention as long as it detects positive and negative values of an input signal using a threshold value. As another example, a peak detector using ATC is Imai, Miyaki's "signal processing PRML, the next generation of mass storage." Japan Nikkei Electronics No. 599, pp 72-79, January, 1994. The peak detector disclosed in this document detects the positive peak value of the input signal when the number of states is binary, since the peak and volume values of the signal essentially correspond to the matrix, and to use the detected value as a new threshold. It prepares to detect the next positive peak value and updates the volume value detection threshold at the same time, and similarly detects the volume value of the input signal, and keeps the detected value to use as a new threshold value. In preparation for the detection of the volumetric value, the threshold for detecting the positive peak value is updated. However, this peak detector may have a problem in that it does not completely update the opposite threshold at a desired time. Therefore, the peak detector shown in Fig. 4 is used for better Viterbi decoding performance. In addition, automatic threshold value control (ATC) means updating threshold values by interlocking them with input signals.

The Viterbi decoder 430 is a PR (+1, -1) Viterbi decoder, and inputs the positive peak value Hn and the volume value Ln detected by the peak detector 420 to perform Viterbi decoding. This Viterbi decoder 430 may also be used for all Viterbi decoders using the Viterbi algorithm, in particular Viterbi decoder (hereinafter referred to as analog Viterbi decoder) that does not require an A / D converter, The detailed configuration and operation of the analog Viterbi decoder whose main configuration is the shift register is disclosed in Korean Application No. "96-11620" and US Patent No. "08 / 743,912" filed by the same applicant. The analog Viterbi decoder has a large advantage that the circuit can be simplified by the existing Viterbi decoder, thereby minimizing the area of the integrated circuit (IC) and lowering the cost and power consumption. Suitable for the product being

The configuration shown in FIG. 4 is used when an analog Viterbi decoder is used, and when using a conventional digital Viterbi decoder, the sampling & hold unit 410 can be replaced with an A / D converter.

The channel demodulator 440 has a (1 + D) characteristic, demodulates the Viterbi decoded data, and outputs the final decoded data. Since the output of the Viterbi decoder 430 is digital data, the channel demodulator 440 may be configured as a de-flip flop that operates according to a driving clock generated by the timing detector 450. 441 may be configured as an exclusive OR gate. The timing detector 450 detects the timing of the equalized reproduction signal and outputs a driving clock necessary for the sampling & hold unit 410, the Viterbi decoder 430, and the channel demodulator 440.

Unlike the apparatus shown in FIG. 1, the data decoding apparatus shown in FIG. 4 does not decode the PR4 (+1, 0, -1) type signal demodulated by the channel demodulator and does not decode the PR (1, -1) channel. ), The peak detector 420 and the Viterbi decoder 430 may be configured with only one channel, and the output of the Viterbi decoder 430 has a (1 + D) channel demodulator ( After demodulation by 440, the final decoded data is output.

However, since the data decoding apparatus shown in Fig. 4 performs peak detection before channel demodulation using the (1 + D) characteristic, when the reproduction signal overlaps a lot of noise, the peak peak that is the output of the peak detector 420 is used. The error of the value Hn and the bulk value Ln increases, which may degrade the performance of the entire decoder. Therefore, the data decoding apparatus shown in FIG. 4 can be applied to a recording / reproducing apparatus including a PR4-type channel having a very good characteristic of noise, and particularly affects the performance of decoded data requiring noise superimposed on the reproduction signal. If the value is small enough not to affect the configuration shown in Figure 4 has excellent competitiveness in terms of ease of implementation or cost.

However, in a magnetic recording and reproducing apparatus using a magnetic head and a magnetic tape as a channel, there are many factors that generate noise. Therefore, the noise level superimposed on the reproduction signal is generally not negligible, and how much can the noise be reduced? Has become an important factor in determining the decoding performance of data.

Here, the main causes of noise are due to tape graininess, head impedance and ultra-short bias resistance of the reproduction amplifier. And the spectrum of the input signal is also changing because it passes through various processors until it reaches a Viterbi decoder such as a reproduction head, a reproduction amplifier and an equalizer.

A data decoding device composed of a state detector and a Viterbi decoder of one channel while responding to such noise is shown in FIG. 5. The sampling & hold unit 510, the peak detector 540, the Viterbi decoder 550, the channel demodulator 560, and the timing detector 570 shown in FIG. Since the same, detailed description of the operation will be omitted.

In Fig. 5, the prefilter 520 having the characteristic (1 + D) delays the output signal Vs of the sampling & hold unit 510 by a period D corresponding to one bit of the recording data and is delayed. And the output signal Vs of the sampling and holding unit 510 are added. Since the characteristics of the prefilter 520 act as a low pass filter, the noise characteristic is improved, but the aperture ratio of the eye pattern is reduced. The prefilter 520 converts the partial response PR (+1, -1) type signal into a partial response PR4 (+1, 0, -1) type signal.

The inverse prefilter 530 has a 1 / (1 + D) characteristic, which is an inverse characteristic of the prefilter 520, and the subtractor 531 has a bulk output from the bulk detector 545 of the peak detector 540. The positive peak value Hn output from the positive peak value detector 543 is subtracted from the value Ln, and the result of the subtraction is delayed by the delay D 532 by a period D corresponding to 1 bit of the recording data. The feedback signal Fs is fed back to the adder 533. The adder 533 adds the output of the prefilter 520 and the feedback signal Fs and outputs it to the peak detector 540. At this time, the feedback signal Fs is a signal having a negative value.

Here, the PR4 (+1, 0, -1) type output signal of the prefilter 520 is returned to the original PR (+1, -1) by the 1 / (1 + D) characteristic of the inverse prefilter 530. The signal can be decoded using only the peak detector 540 and Viterbi protector 550 of one channel, and fed back to the output of the digital peak detector 540 in the noise state in the adder 533 in the noise problem. Since the feedback signal Fs and the output signal of the analog but digital prefilter 520 are added, the feedback signal Fs has the same noise level as the conventional PR4 type system in which a channel demodulator is configured in front of the peak detector and the Viterbi decoder. That is, the data decoding apparatus shown in FIG. 5 has a reproduction characteristic corresponding to a PR4 (+1, 0, -1) type system while the aperture ratio of the eye pattern corresponds to a PR (+1, -1) type system. This improves the Viterbi decoder's performance and simplifies the configuration, giving it a competitive edge.

6A to 6H are operational waveform diagrams of the data decoding apparatus shown in FIG. 5, and FIG. 6A is a waveform of the output signal Vs of the sampling & hold unit 510. FIG. 6B is a waveform of a signal in which the output signal Vs of the sampling & hold unit 510 is delayed by one bit period D of the recording data by the delay unit 522 of the prefilter 520. . FIG. 6C shows the output waveform of the adder 521 of the prefilter 520, and FIG. 6D shows the positive peak value Hn output from the positive peak value detector 543 of the peak detector 540. FIG. (E) is an output waveform of the volume value Ln output from the bulk value detector 545, and (f) of FIG. 6 is a retarder of the inverse prefilter 530. This is the output waveform of the feedback signal Fs output from 532. 6G is a waveform of Viterbi decoded data output from the Viterbi decoder 550, and FIG. 6H is a waveform of final decoded data output from the channel demodulator 560.

FIG. 7 is a data decoding apparatus that can be applied to a digital recording / reproducing apparatus having an E ⁿ PR 4 type channel. For ease of description, the EPR 4 type will be described as an example, and the same components as those of the apparatus shown in FIG. Detailed description thereof will be omitted.

The main difference between the present invention and the conventional EPR4-type system shown in Fig. 2 is that the 8 (= 2 ³ ) -state detector and the 8-state Viterbi decoder consist of the 1-state detector and the Viterbi decoder. It is. In addition, the channel demodulator 680 having a 1 / (1 + D) ² characteristic to be configured at the rear end of the Viterbi decoder 670 in response to the pre-coder of 1 / (1 + D) ² in the EPR4 type system.

The data decoding apparatus of the present invention uses a first prefilter 620 having a (1 + D) characteristic and 1 / (1 + D), which is an inverse characteristic of the prefilter 620, in order for the noise characteristic to correspond to an EPR4-type system. A first peak detector 640 that detects a positive peak value and a volume value from an output of the first inverse prefilter 630 and the first inverse prefilter 630, and feeds back the first inverse prefilter 630; The second prefilter 650 converting the output of the first inverse prefilter 630 into a PR4 (+1, 0, -1) type signal and the output of the second prefilter 650 again PR (+1). And a positive peak value and a volume value are detected from the outputs of the second inverse prefilter 660 and the second inverse prefilter 660 which are converted into a -1) type signal and fed back to the second inverse prefilter 660. Using two prefilters 620 and 650 and two inverse prefilters 630 and 660, including a second peak detector 670, the noise characteristics are applied to the Viterbi decoder 680 while maintaining an EPR4-type system. Input signal type is PR (+1, -1) To use the Viterbi decoder of one channel.

Here, the data decoding apparatus in the case of being applied to a digital recording / reproducing apparatus having an E ⁿ PR4 channel has a prefilter having n + 1 (1 + D) characteristics and n + 1 1 / (1 + D) characteristics. And a channel demodulator having (1 + D) ^{n + 1} characteristics at the rear end of the Viterbi decoder.

Therefore, in the data decoding apparatus applied to the E ⁿ PR4 type system of the present invention, since its channel has the characteristic of (1-D), its output is PR (1, -1) type, which is required by the Viterbi decoding algorithm. With the focus on having a structure in which the present invention has a structure, the purpose is to use a Viterbi decoder of one channel by using this reproduction signal as a decoding signal without converting the reproduced signal into a signal of another type.

In this case, conventionally, since the channel demodulator having the low pass filter characteristic (1 + D) ^{n + 1} is not passed through, the performance of the decoder is degraded under the influence of severe noise. The inverse prefilter that feeds back the peak detector output signal and adds the output signal of the peak detector and the output signal of the prefilter having the low pass filter characteristic (1 + D) is configured at the front of the Viterbi decoder to It is possible to improve the noise to the level of EPR4 (1, 1, -1, -1) while keeping the signal in the PR (+1, -1) state, which greatly improves the implementation of the decoder in the recording and reproducing apparatus having the magnetic channel. It is as easy as that.

In addition, the present invention can be configured not only to correspond to each of the methods of the PR4 type or E ⁿ PR4 type as shown in Figs. 5 and 7, but also can correspond to various methods as shown in Fig. It can also be configured to do so.

Figure 8 is optionally PR4-type or E ⁿ a block diagram of a data decoding apparatus capable of reproducing a PR4-type, The same component parts as compared to the configuration shown in Figure 7, the detailed operation in a digital recording and reproducing apparatus having a PR4-type channel The description is omitted, and for ease of explanation, E ⁿ PR 4 type is described as EPR 4 type.

That is, in FIG. 8, the first inverse prefilter 730 does not increase the noise of the output signal of the first prefilter 720 of the PR4 (1, 0, -1) type without increasing the noise. Reduce to) signal. The second prefilter 750 and the second inverse prefilter 760 are configured in the same manner as the first prefilter 720 and the first inverse prefilter 730 to correspond to the EPR4 decoder.

The first channel demodulator 790 has a structure having a characteristic of (1 + D), and its output is decoded data for a PR4-type system and is input to a first input terminal of the selector 810. The second channel demodulator 800, which is connected to the output terminal of the first channel demodulator 790, has a structure having a characteristic of (1 + D), and its output is decoded data for an EPR4-type system and It is input to the second input terminal. The selector 810 selects the output of the first channel demodulator 790 in the case of the PR4 type according to the mode signals PR4 / EPR4, and selects the output of the second channel demodulator 800 in the case of the EPR4 type.

Therefore, in the digital recording / reproducing apparatus having the PR4-type channel, the data decoding with the EPR4-type shown in FIG. 8 can improve the noise characteristics and increase the aperture ratio of the eye pattern. Therefore, the present invention requires excellent decoding performance. It can be applied to the device.

Further, FIG. 8, but is selectively decoded by the data decoded in the digital recording and reproducing apparatus having a PR4-type channel type PR4-type or EPR4, by adding a precoder, the inverse pre-filter E ² PR, E ³ PR, E ⁴ PR You can optionally decode the various types. In addition, in the digital recording / reproducing apparatus having an E ⁿ PR4 channel, there are applications in which more prefilters and inverse prefilters are configured than (n + 1) to improve noise characteristics and improve eye pattern opening ratio to decode data. Can be.

9 (a) to (l) are operational waveform diagrams of the data decoding apparatus shown in FIG. 8, which show waveforms in which a reproduction signal input to the Viterbi decoder 780 is decoded when noise is not superimposed on a channel. It is shown as.

That is, FIG. 9A illustrates a waveform of a signal Vs output from the sampling & hold unit 710, and FIG. 9B illustrates sampling by the delay unit 722 of the first prefilter 720. &Amp; Waveform of the delayed signal Vs output from the hold group 710, (c) of FIG. 9 is the output waveform of the first prefilter 720, and (d) of FIG. This is a waveform of the feedback signal Fs1 output from the delay unit 732 of the prefilter 730. Since this feedback signal Fs1 was detected from the output signal of the peak detector 740, it was converted into the digital level. Therefore, since the feedback signal Fs1 does not contain analog noise, the first inverse prefilter 730 may perform 1 / (1 + D) operation without increasing the noise.

FIG. 9E illustrates the output waveform of the first inverse prefilter 730, and FIG. 9F illustrates the first inverse prefilter 730 by the delay unit 752 of the second precoder 750. 9 g is a waveform of a positive peak value Hn output from the second positive peak value detector 773, and FIG. 9 h is a second waveform. It is a waveform of the volume value Ln output from the value detector 775.

FIG. 9I is a waveform of the feedback signal Fs2 output from the delay unit 762 of the second inverse prefilter 760, and FIG. 9J is a decoding output from the Viterbi decoder 780. 9 (k) shows the output waveform of the first channel demodulator 790, and FIG. 9 (l) shows the output waveform of the second channel demodulator 800. FIG.

According to the present invention, in a system having a PR4 (+1, 0, -1) channel such as a digital magnetic recording / playback apparatus, the noise is reduced to PR4 (+1, 0, -1 when decoding the playback signal by the Viterbi decoding method. ), While the aperture ratio of the eye pattern is configured to correspond to the PR (+1, -1) system, the performance of the Viterbi decoder is improved compared to the PR4 (+1, 0, -1) system and at the same time PR (+1, By enabling detection in -1) state, a state detector and Viterbi decoder can be configured in one channel to secure breakthrough competitiveness in implementation and cost.

In addition, in the system having an E ⁿ PR 4 type channel such as a digital magnetic recording and reproducing apparatus, when the reproduction signal is decoded by the Viterbi decoding method, the noise corresponds to the E ⁿ PR 4 system and the aperture ratio of the eye pattern is PR ( It is configured to cope with +1, -1) system to improve the performance of Viterbi decoder and to detect at PR (+1, -1) system at the same time. It can secure breakthrough competitiveness.

In addition, the present invention has the effect that the data can be decoded in various types as well as the corresponding type in the system having the PR4 type or E ⁿ PR4 type channel.

Claims (31)

A system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, comprising: a single channel, which is subjected to the most like decoding of a PR (+ 1, -1) type signal received through the channel. A best friend decoder for outputting the best friend decoded data; And a channel demodulator having a (1 + D) characteristic, which is an inverse characteristic of the precoder, and outputting decoded data by channel demodulating the most preferred decoded data. 2. The method of claim 1, wherein the best-decoder decoder defines the PR (+1, -1) type signal according to a forward threshold and a division threshold in association with a PR (+1, -1) type signal received through the channel. A state detector for detecting a state value and a negative state value; And a Viterbi decoder for inputting the positive state value and the negative state value to perform Viterbi decoding. 2. The apparatus of claim 1, further comprising: a sampling and holding unit for sampling and holding a PR (+1, -1) type signal received through the channel; And a timing detector for detecting a timing of a PR (+1, -1) type signal received through the channel and generating driving clocks of the sampling and holding groups, the most like decoder, and the channel demodulator. Data decoding device. 2. The apparatus of claim 1, further comprising: an analog-to-digital (A / D) converter for converting a PR (+1, -1) type signal received through the channel into digital data; And a timing detector for detecting timing of a PR (+1, -1) type signal received through the channel to generate driving clocks of the A / D converter, the likelihood decoder, and the channel demodulator. Data decoding device. A system having a PR4-type channel comprising a precoder having a 1 / (1 + D) characteristic, comprising: a PR (+ 1, -1) type signal having a (1 + D) characteristic and received through the channel A prefilter for converting a PR4 (+1, 0, -1) type signal; An inverse prefilter having a 1 / (1 + D) characteristic and converting the PR4 (+1, 0, -1) type signal back into a PR (+1, -1) type signal; A most preferred decoder comprising one channel and outputting the best decoded data by performing the best like decoding on the PR (+1, -1) type signal outputted from the inverse prefilter; And a channel demodulator having a (1 + D) characteristic, which is an inverse characteristic of the precoder, and outputting decoded data by channel demodulating the most preferred decoded data. 6. The method of claim 5, wherein the most preferred decoder defines the PR (+1, -1) type signal according to a forward threshold and a division threshold in association with a PR (+1, -1) type signal received through the channel. A state detector for detecting a state value and a negative state value; And a Viterbi decoder for inputting the positive state value and the negative state value to perform Viterbi decoding. The apparatus of claim 5, wherein the prefilter comprises: a first delayer configured to delay a PR (+1, −1) type signal received through the channel and output a delay signal; And a first adder for adding a PR (+1, -1) type signal received through the channel and the delay signal to output a first addition signal of PR4 (+1, 0, -1) type. Data decoding device characterized in that. 8. The apparatus of claim 7, wherein the inverse prefilter comprises: a subtractor which subtracts the positive state value from the negative state value; A second delayer configured to delay the output of the subtractor and output a feedback signal; And a second adder which adds the first addition signal and the feedback signal to output a PR (+1, -1) type signal. 6. The apparatus of claim 5, further comprising: a sampling and holding unit for sampling and holding a PR (+1, -1) type signal received through the channel; And a timing detector for detecting a timing of a PR (+1, -1) type signal received through the channel and generating driving clocks of the sampling and holding groups, the most like decoder, and the channel demodulator. Data decoding device. 6. The apparatus of claim 5, further comprising: an A / D converter for converting a PR (+1, -1) type signal received through the channel into digital data; And a timing detector for detecting timing of a PR (+1, -1) type signal received through the channel to generate driving clocks of the A / D converter, the likelihood decoder, and the channel demodulator. Data decoding device. 6. The apparatus of claim 5, wherein the channel demodulator comprises: a flip-flop for unit delaying the best-decoded data; And a logic circuit for exclusively ORing the most-decoded data and the output of the deflip-flop. A system having an E ⁿ PR4-type channel comprising a precoder with 1 / (1 + D) ^{n + 1} characteristics, comprising: PR (+1, −) having a (1 + D) characteristic and received over the channel. 1) Precoder for converting a type signal into a PR4 (+1, 0, -1) type signal, and a positive state and a negative state according to the positive threshold value and the division threshold value linked to the PR (+1, -1) type signal. A state detector for detecting a value has a 1 / (1 + D) characteristic, and feeds back the PR4 (+1, 0, -1) type signal by feeding back the positive state value and the negative state value. A unit connected in series with n + 1 reverse prefilters converted to a -1) type signal and output to the state detector; A Viterbi decoder comprising one channel and outputting Viterbi decoded data by Viterbi decoding a PR (+1, -1) type signal output from the unit; And a channel demodulator having (1 + D) ^{n + 1} characteristics, which are inverse characteristics of the precoder, and outputting decoded data by channel demodulating the Viterbi-decoded data. 13. The apparatus of claim 12, wherein the first precoder of the unit comprises: a first delayer for outputting a first delay signal by unit-delaying a PR (+1, -1) type signal received through the channel; And an adder for adding a PR (+1, -1) type signal received through the channel and the first delayed signal to output a first addition signal of PR4 (+1, 0, -1) type, A second precoder to a n + 1 precoder each of which delays a PR (+1, -1) type signal output from the immediately preceding inverse prefilter and outputs a delay signal; And an adder for outputting a PR4 (+1, 0, -1) type signal by adding the PR (+1, -1) type signal and the delayed signal output from the previous inverse prefilter. Data decoding device. 13. The apparatus of claim 12, wherein each of the inverse prefilters comprises: a subtractor for subtracting the positive state value from a negative state value output from the state detector; A second delayer configured to delay the output of the subtractor and output a feedback signal; And a second adder for adding the output signal of the precoder and the feedback signal. 13. The apparatus of claim 12, further comprising: a sampling and holding unit for sampling and holding a PR (+1, -1) type signal received through the channel; And a timing detector for detecting a timing of a PR (+1, -1) type signal received through the channel and generating driving clocks of the sampling and holding groups, the most like decoder, and the channel demodulator. Data decoding device. 13. The apparatus of claim 12, further comprising: an A / D converter for converting a PR (+1, -1) type signal received through the channel into digital data; And a timing detector for detecting timing of a PR (+1, -1) type signal received through the channel to generate driving clocks of the A / D converter, the likelihood decoder, and the channel demodulator. Data decoding device. 13. The apparatus of claim 12, wherein the channel demodulator comprises: (n + 1) delays connected in series to delay (n + 1) bits the most preferred decoded data; And a logic circuit for exclusively ORing the most decoded data and the outputs of the (n + 1) delay units. A system having a PR4-type channel comprising a precoder having a 1 / (1 + D) characteristic, comprising: a PR (+ 1, -1) type signal having a (1 + D) characteristic and received through the channel Prefilter for converting to PR4 (+1, 0, -1) type signal, and detecting positive and negative state values according to positive threshold value and division threshold value linked to PR (+1, -1) type signal The detector has a 1 / (1 + D) characteristic and converts the PR4 (+1, 0, -1) type signal into a PR (+1, -1) type signal by inputting the positive state value and the negative state value. A unit connected in series with n + 1 reverse prefilters output to the state detector; A Viterbi decoder comprising one channel and outputting Viterbi decoded data by Viterbi decoding a PR (+1, -1) type signal output from the unit; A first channel demodulator having a (1 + D) characteristic which is an inverse characteristic of the precoder and outputting data decoded in a PR4 type by channel demodulating the Viterbi decoded data; A second channel demodulator having (1 + D) ⁿ characteristics, for channel demodulating the output of the first channel demodulator and outputting data decoded in an E ⁿ PR4 type; And a selector for selecting one of the outputs of the first and second channel demodulators according to a PR4 / E ⁿ PR4 mode signal. 19. The apparatus of claim 18, wherein the first precoder of the unit comprises: a first delayer for outputting a first delayed signal by unit-delaying a PR (+1, -1) type signal received through the channel; And an adder for adding a PR (+1, -1) type signal received through the channel and the first delayed signal to output a first addition signal of PR4 (+1, 0, -1) type, A second precoder to a n + 1 precoder each of which delays the PR (+1, -1) type signals outputted from the inverse prefilter unit and outputs a delay signal; And an adder for outputting the PR4 (+1, 0, -1) type signal by adding the PR (+1, -1) type signal and the delay signal output from the immediately preceding inverse prefilter. Data decoding device. 19. The apparatus of claim 18, wherein each of the inverse prefilters comprises: a subtractor for subtracting the positive state value from a negative state value output from the state detector; A second delayer configured to delay the output of the subtractor and output a feedback signal; And a second adder for adding the output signal of the precoder and the feedback signal. 19. The apparatus of claim 18, further comprising: a sampling and holding unit for sampling and holding a PR (+1, -1) type signal received through the channel; And a timing detector for detecting a timing of a PR (+1, -1) type signal received through the channel and generating driving clocks of the sampling and holding groups, the most like decoder, and the channel demodulator. Data decoding device. 19. The apparatus of claim 18, further comprising: an A / D converter for converting a PR (+1, -1) type signal received through the channel into digital data; And a timing detector for detecting timing of a PR (+1, -1) type signal received through the channel to generate driving clocks of the A / D converter, the likelihood decoder, and the channel demodulator. Data decoding device. 19. The apparatus of claim 18, wherein the first channel demodulator comprises: a unit delay unit for unit delaying the most preferred decoded data; And a logic circuit for exclusively ORing the most-decoded data and the output of the unit delayer. 19. The apparatus of claim 18, wherein the second channel demodulator comprises: n delays serially configured to delay n bits of data output from the first channel demodulator; And a logic circuit configured to exclusively OR the data output from the first channel demodulator and the outputs of the n delay units. A system having an E ⁿ PR4-type channel comprising a precoder with 1 / (1 + D) ^{n + 1} characteristics, comprising: PR (+1, −) having a (1 + D) characteristic and received over the channel. 1) Pre-filter converting type signal into PR4 (+1, 0, -1) type signal, positive state value and negative state according to positive threshold value and division threshold value linked to PR (+1, -1) type signal A state detector for detecting a value, having a characteristic of 1 / (1 + D) and inputting the positive state value and a negative state value to regenerate the PR4 (+1, 0, -1) type signal again to PR (+1, -1). A unit connected in series with m (m is an integer greater than n + 1) in which a pre-filter converted into a) signal and output to the state detector; A Viterbi decoder comprising one channel and outputting Viterbi decoded data by Viterbi decoding a PR (+1, -1) type signal output from the unit; A first channel demodulator having a (1 + D) ^{n + 1} characteristic that is an inverse characteristic of the precoder and outputting first decoded data by channel demodulating the Viterbi decoded data; A second channel demodulator having a characteristic of (1 + D) ^p (where p = mn−1) and outputting second decoded data by channel demodulating the output of the first channel demodulator; And a selector for selecting one of the outputs of the first and second channel demodulators in accordance with a mode signal. A data decoding method of a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, the method comprising: (a) directly applying a PR (+ 1, -1) type signal received through the channel; Decoding and outputting the most decoded data; And (b) outputting decoded data by adding delayed data and the most preferred decoded data by unit-delaying the best-decoded data to have (1 + D) characteristics, which are inverse characteristics of the precoder. Data decoding method characterized in that. 27. The method of claim 26, wherein the step (a) comprises: (a1) the PR (+1, -1) according to the forward threshold and the division threshold in association with a PR (+1, -1) type signal received through the channel; Detecting a positive state value and a negative state value of the) -type signal; And (a2) inputting the positive state value and the negative state value to decode Viterbi. A data decoding method of a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, comprising: (a) a PR (+1) received through the channel to have a (1 + D) characteristic; Delaying the -1) type signal by a unit bit and adding the delayed signal and the PR (+1, -1) type signal to convert the PR4 (+1, 0, -1) type signal; (b) subtracting the PR4 (+1, 0, -1) type signal from the feedback signal and converting the PR4 (+1, -1) type signal back into a PR (+1, -1) type signal to have a 1 / (1 + D) characteristic; (c) Positive and negative states of the PR (+1, -1) type signal according to the positive and division thresholds linked to the PR (+1, -1) type signal converted in step (b). Detecting a value and outputting the feedback signal obtained by adding a negative state value and an inverse positive state value; (d) inputting the positive state value and the negative state value to perform Viterbi decoding to output the Viterbi-decoded data; And (e) delaying the Viterbi-decoded data to have (1 + D) characteristics, which are inverse characteristics of the precoder, adding delayed data and the Viterbi-decoded data and outputting decoded data. Data decoding method characterized in that. A data decoding method of a system having an E ⁿ PR4-type channel including a precoder having 1 / (1 + D) ^{n + 1} characteristics, comprising: (a) reception through the channel to have (1 + D) characteristics; Unit-delaying the PR (+1, -1) type signal to add the delayed signal and the PR (+1, -1) type signal and converting it into a PR4 (+1, 0, -1) type signal; (b) subtracting the PR4 (+1, 0, -1) type signal from the feedback signal and converting the PR4 (+1, -1) type signal back into a PR (+1, -1) type signal to have a 1 / (1 + D) characteristic; (c) Positive and negative states of the PR (+1, -1) type signal according to the positive and division thresholds linked to the PR (+1, -1) type signal converted in step (b). Detecting a value and outputting the feedback signal obtained by adding a negative state value and an inverse positive state value; (d) repeating steps (a) to (c) n + 1 times; (e) outputting Viterbi-decoded data by Viterbi decoding the PR (+1, -1) type signal output after performing step (d); And (f) adding the data obtained by delaying the Viterbi decoded data n + 1 bits and the Viterbi decoded data to have (1 + D) ^{n + 1} characteristics, which are inverse characteristics of the precoder, to decode the decoded data. And outputting the data. A data decoding method of a system having a PR4-type channel including a precoder having a 1 / (1 + D) characteristic, comprising: (a) a PR (+1) received through the channel to have a (1 + D) characteristic; Delaying the -1) type signal by a unit bit and adding the delayed signal and the PR (+1, -1) type signal to convert the PR4 (+1, 0, -1) type signal; (b) subtracting the PR4 (+1, 0, -1) type signal from the feedback signal and converting the PR4 (+1, -1) type signal back into a PR (+1, -1) type signal to have a 1 / (1 + D) characteristic; (c) Positive and negative states of the PR (+1, -1) type signal according to the positive and division thresholds linked to the PR (+1, -1) type signal converted in step (b). Detecting a value and outputting the feedback signal obtained by adding a negative state value and an inverse positive state value; (d) repeating steps (a) to (c) n + 1 times; (e) outputting Viterbi-decoded data by Viterbi decoding the PR (+1, -1) type signal output after performing step (d); (f) delaying the Viterbi-decoded data by a unit bit to have (1 + D) characteristics, which are inverse characteristics of the precoder, adding delayed data and the Viterbi-decoded data and outputting data decoded in the PR4 type. Doing; (g) (1+ D) by the method comprising n-bit delaying the PR4-type decoded data to have a characteristic ⁿ n-bit-delayed data and adding the decoded data to the PR4-type output data decoded by E ⁿ PR4-type; And (h) PR4 / E ⁿ PR4 mode signal in accordance with the data decoding method, characterized in that it comprises the step of selecting one of the data and the data decrypted by E ⁿ PR4-type decoded by the PR4-type. A data decoding method of a system having an E ⁿ PR4-type channel including a precoder having 1 / (1 + D) ^{n + 1} characteristics, comprising: (a) reception through the channel to have (1 + D) characteristics; Unit-delaying the PR (+1, -1) type signal to be added and converting the delayed signal and the PR (+1, -1) type signal into a PR4 (+1, 0, -1) type signal; (b) subtracting the PR4 (+1, 0, -1) type signal from the feedback signal and converting the PR4 (+1, -1) type signal back into a PR (+1, -1) type signal to have a 1 / (1 + D) characteristic; (c) Positive and negative states of the PR (+1, -1) type signal according to the positive and division thresholds linked to the PR (+1, -1) type signal converted in step (b). Detecting a value and outputting the feedback signal obtained by adding a negative state value and an inverse positive state value; (d) repeating steps (a) to (c) m (m is an integer greater than n + 1); (e) outputting Viterbi-decoded data by Viterbi decoding the PR (+1, -1) type signal output after performing step (d); (f) delaying the Viterbi-decoded data by (n + 1) bits to have (1 + D) ^{N + 1} characteristics, which are inverse characteristics of the precoder, and (n + 1) -bit delayed data and the Viterbi decoding Adding the decoded data and outputting first decoded data decoded in E ⁿ PR4 type; And (g) p-delay the first decoded data to have a characteristic of (1 + D) ^p (p = mn-1) to add the delayed p-bit data and the first decoded data to output second decoded data. Doing; And (h) selecting one of the first and second decoded data according to a mode signal.

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